JP2004352399A - Double feed sensing device and image reading apparatus equipped with it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a double feed sensing device and an image reading apparatus equipped with it capable of precluding misjudgement that sheets are double fed when a sheet as thick as two ordinary sheets overlapped one over the other is fed or when sheets of different thickness are fed. <P>SOLUTION: The double feed sensing device 21 is equipped with RGB, three-colored LEDs 11 to illuminate a sheet with an image formed thereon, a light receiving sensor 12 to receive the reflection light from the sheet irradiated with the light from the LEDs, an infrared LED 15 to irradiate the sheet with irradiation light having different characteristics from the light from the LEDs, a light receiving sensor 14 irradiated with the light from the infrared LED and to receive the light having penetrated the sheet, and a CPU circuit 5 to judge whether sheets are double fed upon comparing the reflection image information obtained by the sensor 12 with the penetrative image information obtained by the sensor 14. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a multi-feed sheet detecting device for detecting whether or not sheets are being conveyed in an overlapped manner, particularly, a reflected image information obtained by light reflected on the sheet and a transmitted image obtained by light transmitted through the sheet. The present invention relates to a multi-feed sheet detection device that detects double feed of sheets by comparing information with each other to determine whether they are the same, and an image reading device including the multi-feed sheet detection device.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is an image reading apparatus that reads images of a plurality of sheet-like members mounted on a tray one by one. If the image reading apparatus does not reliably read the image of the sheet-like member one by one, a part of the read information will be lost. For this reason, the image reading apparatus is often equipped with a multi-feed sheet detecting device that detects the double feeding of the sheet-shaped member when the sheet-shaped member is sent in an overlapping manner (an example of the sheet detecting device). See Patent Document 1).
[0003]
The sheet-like member is formed of plain paper, a thin resin sheet which is a substitute for plain paper, photosensitive paper, OHP (overhead projector) paper, an envelope, and a roll on which an image can be formed. There is a type in which a roll of long paper is fed, cut, and conveyed, and is hereinafter generally referred to as a “sheet”.
[0004]
Conventional multi-feed sheet detection devices use infrared light to detect multi-feed of sheets. The multi-feed sheet detection device 101 shown in FIG. 12 detects multi-feed of sheets using infrared rays. The double feed sheet detecting device 101 irradiates the sheet P with infrared rays emitted from the infrared light emitter 107 and receives the transmitted infrared light that has passed through (passed through) the sheet P with the infrared light receiver 108. I have. The infrared light emitter 107 has a light emitting diode (LED), that is, an infrared LED. The infrared receiver 108 is disposed at a position facing the infrared emitter 107 with the sheet P interposed therebetween.
[0005]
The transmitted infrared light transmitted through the sheet is received by the infrared receiver 108. The infrared receiver 108 sends the transmitted infrared signal to the AD converter 104. The A / D converter 104 converts the transmitted infrared signal from an analog signal to a digital signal. The transmitted infrared signal converted into a digital signal by the A / D converter 104 is input to a CPU circuit 105 as a control unit.
[0006]
The CPU circuit 105 determines whether or not the value of the light receiving intensity of the transmitted infrared ray falls within a range between the first specified value and the second specified value stored in advance in the memory 106 serving as a storage unit. As shown in FIG. 13, when the value of the received light intensity falls between the first specified value and the second specified value, the CPU circuit 105 determines that the sheet has not been multi-fed, and When the value does not fall between the specified value and the second specified value, it is determined that the sheet is multi-fed.
[0007]
[Patent Document 1]
JP-A-8-48439 (FIGS. 1 and 2)
[0008]
[Problems to be solved by the invention]
However, the conventional multi-feed sheet detecting device irradiates the infrared ray emitted from the infrared light emitting device to the conveyed sheet, receives the transmitted infrared light transmitted through the sheet with the infrared light receiving device, and receives the infrared light received by the infrared light receiving device. Since the thickness of the sheet is determined from the value of the intensity of the transmitted infrared light, when a sheet having the same thickness as two or more stacked sheets is conveyed, or a sheet of various thickness Has been conveyed, there is a case where the sheet is erroneously recognized as being multi-fed even if the sheet is conveyed correctly.
[0009]
The present invention does not mistakenly recognize that a sheet is a double feed when a sheet having a thickness similar to the thickness of two or more stacked sheets is conveyed, or when a sheet of various thickness is conveyed. It is an object of the present invention to provide a multi-feeding sheet detecting device.
[0010]
SUMMARY OF THE INVENTION It is an object of the present invention to provide an image reading apparatus that includes the above-described multi-feed sheet detecting device in an apparatus main body and reads an image of a sheet.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, a multi-feed sheet detection device according to the present invention includes a first irradiation unit that irradiates a sheet on which an image is formed, and receives reflected light from the sheet irradiated by the first irradiation unit. A first light receiving unit, a second irradiating unit that irradiates the sheet with irradiation light having characteristics different from those of the first irradiating unit, and receives transmitted light that has been transmitted by the second irradiation unit and transmitted through the sheet. A second light receiving means for comparing the reflected image information obtained by the first light receiving means with the transmitted image information obtained by the second light receiving means to determine whether or not the sheet is multi-fed. Determining means.
[0012]
In order to achieve the above object, a multi-feed sheet detection device according to the present invention includes a first irradiation unit that irradiates a sheet on which an image is formed, and receives reflected light from the sheet irradiated by the first irradiation unit. A first light receiving unit, a second irradiating unit that irradiates the sheet with irradiation light having characteristics different from those of the first irradiating unit, and receives transmitted light that has been transmitted by the second irradiation unit and transmitted through the sheet. A second light receiving unit that inverts one of the reflected image information obtained by the first light receiving unit and the transmitted image information obtained by the second light receiving unit and compares the image information with the other image information Determining means for determining whether or not the sheet is multi-fed based on whether or not both pieces of image information are the same.
[0013]
In order to achieve the above object, a multi-feed sheet detection device according to the present invention includes a first irradiation unit that irradiates a sheet on which an image is formed, and receives reflected light from the sheet irradiated by the first irradiation unit. A first light receiving unit, a second irradiating unit that irradiates the sheet with irradiation light having characteristics different from those of the first irradiating unit, and receives transmitted light that has been transmitted by the second irradiation unit and transmitted through the sheet. A second light receiving means, a third light emitting means for irradiating the back surface of the sheet irradiated by the first light emitting means, and a third light receiving means for receiving the reflected light from the back surface irradiated by the third light emitting means And first overlap image information obtained by superimposing the reflected image information obtained by the first light receiving means and the inverted reflected image information obtained by the third light receiving means; Transmitted image information The first superimposed image information is inverted by inverting one superimposed image information of the second superimposed image information obtained by superimposing the reflected image information obtained by the third light receiving unit and the second superimposed image information. And a judging means for judging whether or not the sheet is multi-fed based on whether or not the second overlap image information is the same.
[0014]
In order to achieve the above object, a multi-feed sheet detection device according to the present invention includes a first irradiation unit that irradiates a sheet on which an image is formed, and receives reflected light from the sheet irradiated by the first irradiation unit. A first light receiving unit, a second irradiating unit that irradiates the sheet with irradiation light having characteristics different from those of the first irradiating unit, and receives transmitted light that has been transmitted by the second irradiation unit and transmitted through the sheet. A second light receiving means, a third light emitting means for irradiating the back surface of the sheet irradiated by the first light emitting means, and a third light receiving means for receiving the reflected light from the back surface irradiated by the third light emitting means A first overlapped image information obtained by superimposing the inverted reflected image information obtained by the first light receiving means and the reflected image information obtained by the third light receiving means; Transmitted image information Comparing the reflected image information obtained by the third light receiving means with the second superimposed image information obtained by superimposing the reflected image information, it is determined whether the first superimposed image information and the second superimposed image information are the same. Determining means for determining whether or not the sheet is multi-fed based on the sheet.
[0015]
In the multi-feed sheet detecting device of the present invention, the second irradiating means can irradiate a part of the conveyed sheet, and the determining means corresponds to a part of the sheet obtained by the first light receiving means. When the difference between the image ratio of the reflection image information and the image ratio of the transmission image information of a part of the sheet obtained by the second light receiving unit is larger than a predetermined value, it is determined that the sheet is being multi-fed. It is supposed to.
[0016]
In the multi-feed sheet detecting device of the present invention, the second irradiating means can irradiate a part of the conveyed sheet, and the determining means corresponds to a part of the sheet obtained by the first light receiving means. The sheet is multi-fed when a difference of a predetermined value or more occurs between a value obtained by differentiating the reflected image information and a value obtained by differentiating the transmitted image information of a part of the sheet obtained by the second light receiving unit. And judge it.
[0017]
In the multi-feed sheet detecting device according to the present invention, the determining unit compares the reflected image information obtained by the first light receiving unit with the transmitted image information obtained by the second light receiving unit, and outputs an image on only one side. It is configured to determine whether or not the sheet is multi-fed based on whether or not the reflection image information and the transmission image information of the sheet on which is formed are the same.
[0018]
In the multi-feed sheet detecting device of the present invention, the determining unit compares the reflected image information obtained by the first light receiving unit with the transmitted image information obtained by the second light receiving unit, and an image is formed on both sides. It is determined whether or not the sheet is multi-fed based on whether or not the reflection image information and the transmission image information on one side of the formed sheet are the same.
[0019]
In the multi-feed sheet detecting device of the present invention, the second light receiving means and the third light receiving means are common light receiving means.
[0020]
In the multi-feed sheet detecting device of the present invention, the first irradiating means and the second irradiating means irradiate a part of the sheet.
[0021]
In the multi-feed sheet detecting device according to the present invention, the first irradiating unit, the second irradiating unit, and the third irradiating unit irradiate a part of the sheet.
[0022]
In the multi-feed sheet detecting device according to the present invention, the first irradiating unit and the second irradiating unit are housed in a common case.
[0023]
In the multi-feed sheet detection device of the present invention, the first irradiation unit and the second irradiation unit are housed in separate cases.
[0024]
In the multi-feed sheet detecting device according to the present invention, the second irradiation unit emits infrared light.
[0025]
In the multi-feed sheet detection device according to the present invention, the second irradiating means has an infrared LED that emits infrared light.
[0026]
In the multi-feed sheet detecting device according to the present invention, the second irradiation unit does not emit light when the determination unit does not operate.
[0027]
The multi-feeding sheet detecting device according to the present invention includes a warning unit that warns that the determination unit is inoperable when the amount of light received by the second light receiving unit is equal to or less than a set value.
[0028]
In order to achieve the above object, an image reading apparatus of the present invention includes: an image reading unit that reads an image formed on a sheet; and a multifeed sheet detection device that detects whether or not the conveyed sheets overlap. Wherein the multi-feed sheet detection device is the multi-feed sheet detection device according to any one of the above, and the image reading means is the first irradiation unit and the first light receiving unit of the multi-feed sheet detection device, and An image is read by the third irradiation means and the third light receiving means.
[0029]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a multi-feeding sheet detection device according to an embodiment of the present invention and an image reading device including the multi-feeding sheet detection device will be described with reference to the drawings.
[0030]
(Multi-feed sheet detection device and image reading device of the first embodiment)
FIG. 1 is a schematic diagram of a multi-feed sheet detection device according to a first embodiment of the present invention and an image reading device including the multi-feed sheet detection device.
[0031]
The image reading device 22 reads an image formed on the sheet-like member P. The sheet-like member is formed of plain paper, a thin resin sheet which is a substitute for plain paper, photosensitive paper, OHP (overhead projector) paper, envelopes, and roll-wound sheets on which images can be formed. There is a type in which a long sheet is fed, cut, and conveyed. In the present invention, the sheet is generally referred to as a “sheet”.
[0032]
The image reading device 22 reads the image formed on the sheet conveyed by the pair of rollers 23 and 24 by the line sensor units 2 and 3. The line sensor units 2 and 3 are configured to read image information on both sides of the sheet by passing the sheet.
[0033]
Each of the line sensor units 2 and 3 has a light source and a light receiving sensor, irradiates red, green, and blue (hereinafter, referred to as “RGB”) visible light from the light source to the sheet and receives reflected light from the sheet. The sensor receives the light.
[0034]
Conventionally, the light source of the line sensor unit 2 uses RGB three-color LED or white cold cathode fluorescent light. However, in order to realize the multi-feed sheet detecting device of the present invention, infrared light is used in addition to visible light. Image data needs to be acquired, and infrared LEDs have been added to conventional light sources.
[0035]
That is, the line sensor unit 2 is, for example, an RGB three-color LED 11 that is a first irradiation unit that emits visible light as a light source, and an infrared light emitter that emits infrared light that has a longer wavelength than visible light and easily transmits a substance. For example, an infrared LED 15 as a means is provided. Further, the line sensor unit 2 has, for example, a light receiving sensor 12 which is a first light receiving unit that receives reflected light reflected by the RGB three-color LEDs 11 irradiating the sheet P.
[0036]
The line sensor unit 3 receives the transmitted light (infrared light) emitted from the infrared LED 15 of the line sensor unit 2 and transmitted through the sheet. It has, for example, a light receiving sensor 14 which is a certain second light receiving means and a third light receiving means. Further, the line sensor unit 3 has, for example, an RGB three-color LED 13 as a third irradiation unit that emits visible light as a light source.
[0037]
The light receiving sensor 14 is arranged at a position where it can receive the reflected light emitted from the RGB three-color LED 13 and reflected by the sheet. That is, the light receiving sensor 14 is arranged at a position where it can receive the transmitted light of the infrared LED 15 transmitted through the sheet and the reflected light of the RGB three-color LED 13 reflected on the sheet.
[0038]
Note that white cold cathode fluorescent light may be used instead of the RGB three-color LEDs 11 and 13.
[0039]
Further, the light receiving sensors 12 and 14 have a plurality of light receiving elements which are photoelectric conversion elements arranged in a plurality in a main scanning direction orthogonal to the sheet conveying direction. Also, a plurality of infrared LEDs 15 are arranged along the main scanning direction. Further, it is preferable that the reflected light of the RGB three-color LED 13 and the transmitted infrared light of the infrared LED 15 have the same optical axis.
[0040]
The reflected image information by the reflected light of the RGB three-color LEDs 11 and 13 obtained from the line sensor units 2 and 3 and the transmitted image information by the infrared transmitted light of the infrared LED 15 obtained from the line sensor unit 3 are AD-converted. The signal is input to the device 4 and converted from an analog signal to a digital signal.
[0041]
The reflected image information and the transmitted image information that have been converted into digital signals by the A / D converter 4 are input to, for example, a CPU circuit 5 which is a determination unit. The CPU circuit 5 processes the reflected image information as a read image. Further, the CPU circuit 5 processes the reflected image information and the transmitted image information so that the reflected image information and the transmitted image information can be used for detecting the double feed of the sheet. The image information processed by the CPU circuit 5 is stored in the memory 6.
[0042]
A description will be given of a double-feed detecting operation when sheets on which an image is formed on only one side overlap and pass between the line sensor units 2 and 3. In this case, there is no need to operate the RGB three-color LEDs 13 of the line sensor unit 3. If the operation of the RGB LED 13 is stopped, the power consumption of the image reading apparatus can be reduced. First, an image reading operation and a multi-feed detection operation when only one sheet of “K” is conveyed will be described with reference to FIGS. 1 and 2.
[0043]
The irradiation light of the RGB three-color LEDs 11 is reflected by the sheet P and received by the light receiving sensor 12. The light receiving sensor 12 reads “K” as it is. This reflection image information is denoted by G1. In this reflection image information, G1 is a read image. On the other hand, the infrared light of the infrared LED 15 passes through the sheet P and is received by the light receiving sensor 14. However, since the light receiving sensor 14 is in the same state as when the sheet is viewed from the back side, "K" is read in the opposite direction. This transparent image information is denoted by G2. Therefore, the CPU circuit 5 inverts the transmitted image information read by the light receiving sensor 14 and changes the direction of the read “K” to a normal direction. This transmission image information is denoted by G3.
[0044]
Then, the CPU circuit 5 superimposes the character “K” read by the light receiving sensor 12 of the line sensor unit 2 and the character “K” read and inverted by the light receiving sensor 14 of the line sensor unit 3 to “K”. It is determined whether the characters "" match. That is, the CPU circuit 5 determines whether or not the reflected image information G1 and the transmitted image information G3 match. In this case, since they match, the CPU circuit 5 determines that the sheets are not conveyed overlapping and continues the reading operation of the sheets thereafter.
[0045]
In the above description, the transmission image information read by the light receiving sensor 14 of the line sensor unit 3 is not inverted, but the reflection image information read by the light receiving sensor 12 of the line sensor unit 2 is inverted, and both image information are superimposed. You may. That is, the reflection image information G1 may be inverted without inverting the transmission image information G2, and both pieces of image information may be overlapped.
[0046]
Next, as shown in FIG. 3, an image reading operation and a double-feed detection operation when a sheet P written “K” and a sheet P1 written “B” are multi-fed, A description will be given based on FIGS.
[0047]
The irradiation light of the RGB three-color LEDs 11 is reflected by the sheet P and received by the light receiving sensor 12. The light receiving sensor 12 reads “K” as it is. This reflection image information is denoted by G1. This reflection image information G1 is a read image. On the other hand, the infrared light of the infrared LED 15 passes through the two sheets P and P1 and is received by the light receiving sensor 14. However, since the light receiving sensor 14 is in the same state as when the sheet is viewed from the back side, "K" and "B" are overlapped and read in the opposite direction. This transparent image information is denoted by G4. Then, the CPU circuit 5 reverses the transmission image information of the light receiving sensor 14 and changes the direction of the overlapped “K” and “B” to the normal direction. This transmission image information is denoted by G5.
[0048]
Then, the CPU circuit 5 superimposes the character “K” read by the light receiving sensor 12 of the line sensor unit 2 and the character “K” and “B” read by the light receiving sensor 14 of the line sensor unit 3. In addition, it is determined whether or not the character “K” matches. That is, the CPU circuit 5 determines whether or not the reflected image information G1 and the transmitted image information G5 match. In this case, "K" matches. However, "B" has no matching character. Accordingly, the CPU circuit 5 determines that the sheets are being conveyed in an overlapping manner, and notifies the user of the fact that the sheets are being multi-fed by the warning unit 16. In this case, the operation of the image reading device 22 may be stopped.
[0049]
The warning means includes a display panel for displaying a notification item, a sound generator for notifying the notification item by voice, an alarm device for generating a warning sound, and the like.
[0050]
In the above description, the transmitted image information read by the light receiving sensor 14 of the line sensor unit 3 is not inverted, but the reflected image information read by the light receiving sensor 12 of the line sensor unit 2 is inverted, and the images may be superimposed. . That is, the transmission image information G4 and the reflection image information obtained by inverting the reflection image information G1 may be superimposed.
[0051]
Next, a multi-feed detecting operation in a case where a sheet P2 written with “K” on the front and “B” on the back is mixed when trying to acquire image information of only one side of the sheet is shown in FIG. 1, will be described with reference to FIG.
[0052]
The irradiation light of the RGB three-color LEDs 11 is reflected by the sheet P2 and received by the light receiving sensor 12. The light receiving sensor 12 reads “K” as it is. This reflection image information is denoted by G1. The reflection image information G1 is a read image. On the other hand, the infrared light of the infrared LED 15 passes through the sheet P2 and is received by the light receiving sensor 14. However, the light receiving sensor 14 reads “B” as it is, but reads “K” in the opposite direction because the state is the same as when the sheet is viewed from the back side. Therefore, the light receiving sensor 14 reads “B” in the normal direction and “K” in the opposite direction in an overlapping manner. This transmission image information is denoted by G6.
[0053]
Then, the CPU circuit 5 inverts the transmission image information G6. The symbol G7 is assigned to the inverted transmission image information. The CPU circuit 5 superimposes the character “K” read by the light receiving sensor 12 of the line sensor unit 2 and the character of the transmission image information G7. That is, the CPU circuit 5 determines whether or not the reflected image information G1 and the transmitted image information G7 match. In this case, "K" matches. However, "B" has no matching character. Therefore, the CPU circuit 5 determines that the sheet having the image formed on both sides is interleaved with the sheet having the image formed on only one side.
[0054]
However, the comparison between the reflection image information G1 and the transmission image information G7 is the same as the comparison between the reflection image information G1 and the transmission image information G5 (see FIG. 3). It will also judge that. In any case, the CPU circuit 5 determines that the conveyed sheet is in an abnormal state, and notifies the user that the sheet conveyance state is abnormal by the warning unit 16. In this case, the CPU circuit 5 may stop the operation of the image reading device 22.
[0055]
As described above, the multi-feed sheet detection device 21 of the present embodiment not only detects the multi-feed of the sheet but also detects the multi-feed of the sheet when detecting the multi-feed of the sheet having the image formed on one side. Even if there is no sheet, when the sheet on which the image is formed on the back side is sent, the sheet can be detected, so that it is possible to prevent the image reading device 22 from missing the image information.
[0056]
In the above description, the transmission image information read by the light receiving sensor 12 of the line sensor unit 2 is not inverted, but the reflection image information read by the light receiving sensor 12 of the line sensor unit 2 is inverted, and the transmission image information is superimposed. Is also good. That is, the transmission image information G6 and the reflection image information obtained by inverting the reflection image information G1 may be superimposed.
[0057]
Next, a multi-feed detection operation when sheets having images formed on both sides thereof overlap and pass between the line sensor units 2 and 3 will be described.
[0058]
First, the image reading operation and the multi-feed detection operation when only one sheet with “K” written on the front and “B” on the back is conveyed will be described with reference to FIGS. I will explain.
[0059]
The irradiation light of the RGB three-color LEDs 11 is reflected by the sheet P2 and received by the light receiving sensor 12. The light receiving sensor 12 reads “K” as it is. This reflection image information is denoted by G11. The irradiation light of the RGB three-color LEDs 13 is reflected by the sheet P2 and received by the light receiving sensor 14. The light receiving sensor 14 reads “B” as it is. This reflection image information is denoted by G12. The reflection image information G11 and the reflection image information G12 are read images. Then, the CPU circuit 5 inverts “B”. This reflection image information is denoted by G13. The CPU circuit 5 superimposes the reflection image information G11 and the reflection image information G13. This reflection image information is denoted by G14. The reflection image information G14 is an example of first overlay image information.
[0060]
On the other hand, the infrared light of the infrared LED 15 passes through the sheet P2 and is received by the light receiving sensor 14. The light receiving sensor 14 reads “B” as it is. However, since the light receiving sensor 14 is in the same state as when the sheet is viewed from the back side, "K" is read in the opposite direction. Therefore, the light receiving sensor 14 reads an image in a state where “B” in the normal direction and “K” in the opposite direction are overlapped. This transmission image information is denoted by G15. The transmission image information G15 is an example of second overlay image information.
[0061]
The CPU circuit 5 inverts the transmission image information G15. G16 is assigned to the inverted transmission image information. Finally, the CPU circuit 5 superimposes the reflection image information G14 and the transmission image information G16 and determines whether or not they match. Since the sheets are not multi-fed, the transmission image information G16 and the reflection image information G14 match. The CPU circuit 5 determines that the sheets are not overlapped and conveyed, and continues the sheet reading operation thereafter.
[0062]
In the above description, the reflection image information G14 may be inverted and superimposed on the transmission image information G15.
[0063]
Further, the reflection image information G11 may be inverted and the reflection image information G12 may be superimposed on the reflection image information, for example, as the first overlay image information, and the transmission image information G15, for example, as the second overlay image information, may be superimposed.
[0064]
Next, a sheet P2 written with "K" on the front and "B" on the back and a sheet P3 written with "C" on the front and "D" on the back are stacked and conveyed. The operation of reading an image and detecting a double feed at the time of reading will be described with reference to FIGS.
[0065]
The irradiation light of the RGB three-color LEDs 11 is reflected by the sheet P2 and received by the light receiving sensor 12. The light receiving sensor 12 reads “K” as it is. This reflection image information is denoted by G11. The irradiation light of the RGB three-color LEDs 13 is reflected by the sheet P3 and received by the light receiving sensor 14. The light receiving sensor 14 reads “D” as it is. This reflection image information is denoted by G17. Then, the CPU circuit 5 inverts “D”. G18 is assigned to the inverted reflection image information. Overlap "D" and "K" in opposite directions. This reflection image information is denoted by G19.
[0066]
On the other hand, the infrared light of the infrared LED 15 passes through the two sheets P2 and P3 and is received by the light receiving sensor 14. The light receiving sensor 14 reads “B” and “D” as they are. However, since the light receiving sensor 14 is in the same state as when the sheet is viewed from the back side, it reads "K" and "C" in opposite directions. Therefore, the light receiving sensor 14 reads in a state where “B” and “D” in the normal directions and “K” and “C” in the opposite directions are overlapped. This transmission image information is denoted by G20.
[0067]
The CPU circuit 5 inverts the transmission image information G20. G21 is assigned to the inverted transmission image information. Finally, the CPU circuit 5 superimposes the reflection image information G19 and the transmission image information G21. "K" and "D" match, but "C" and "D" have no matching characters.
[0068]
Accordingly, the CPU circuit 5 determines that the sheets are being conveyed in an overlapping manner, and notifies the user of the fact that the sheets are being multi-fed by the warning unit 16. In this case, the operation of the image reading device 22 may be stopped.
[0069]
Further, since the sheets are multi-fed, the image reading device 22 reads the character “K” on the upper sheet but does not read the character “B”. Instruct 16 to reread.
[0070]
In the above description, the reflection image information G19 may be inverted and superimposed on the transmission image information G20.
[0071]
Further, the transmission image information G20 may be superimposed on the reflection image information obtained by inverting the reflection image information G11 and superimposing the reflection image information G17.
[0072]
When only one side of the sheet is read, the RGB three-color LEDs 13 of the line sensor unit 3 are unnecessary.
[0073]
Further, the line sensor unit 2 is disposed above the sheet and the line sensor unit 3 is disposed below the sheet. However, the line sensor unit 2 is disposed below the sheet and the line sensor unit 3 is disposed below the sheet. The unit 3 may be arranged above the seat.
[0074]
As described above, the multi-feed sheet detection device 21 described above is configured to compare the entire read image and detect whether or not a sheet is multi-fed, but to compare a part of the read image. Alternatively, it may be configured to detect whether or not the sheet is multi-fed. In this case, the cost of the multi-feed sheet detection device 21 can be reduced. Further, the amount of information for detecting a multi-feed sheet can be reduced, and the multi-feed detection speed can be increased.
[0075]
(Multi-feed sheet detection device and image reading device of second embodiment)
It is also possible to detect whether or not the sheet is multi-fed using the acquired waveform of the reflected image information by visible light and the acquired waveform of the transmitted image information by infrared light. That is, since infrared rays have different absorption intensities in the infrared spectrum depending on the irradiated substance, the infrared transmission intensity is reduced in a portion where ink or the like is attached to the sheet. It is possible to detect whether or not the sheet is multi-fed using the difference in infrared absorption intensity characteristics.
[0076]
For example, it is possible to detect whether or not the sheet is multi-fed by differentiating the waveform. Hereinafter, the embodiment will be described.
[0077]
As shown in FIG. 7, the image reading device 29 provided with the multi-feed sheet detecting device 28 receives the transmitted light and the reflected light with the separate light receiving sensors 25 and 26, and uses the second irradiation unit. For example, an infrared LED 27 is housed in a case 19 separated from the case 17, and a second light receiving means for detecting infrared transmitted light, for example, a light receiving sensor 26, and a third light receiving means for receiving reflected light, for example, light receiving The sensor 25 and the case 25 are housed in separate cases 20 and 18.
[0078]
The configuration shown in FIG. 7 has a configuration in which an infrared LED 27 and a light receiving sensor 26 are added to a conventional image reading apparatus.
[0079]
As shown in FIG. 8, one infrared LED 27 is provided at a central portion in a direction orthogonal to the sheet conveying direction. The light receiving sensor 26 is provided at a position facing the infrared LED 27. The light receiving sensors 12 and 25 have light receiving elements 12a and 25a, which are a plurality of photoelectric conversion elements arranged along a main scanning direction orthogonal to the sheet conveying direction. The light receiving elements 12an and 25an disposed at positions corresponding to the infrared LEDs 27 are used.
[0080]
Note that the infrared LED 27 does not necessarily need to be provided at the center. What is necessary is just to arrange | position in the area | region of the image formed in the sheet | seat. Further, the number of infrared LEDs 27 need not be one. Several pieces may be arranged in a part of the area of the image formed on the sheet.
[0081]
The CPU circuit 5 differentiates the waveform in one line of the target image (the line along the sub-scanning direction (sheet conveying direction)) obtained by the waveform of the reflected image information obtained from the light receiving element 12an (or the light receiving element 25an). The sign of the value thus obtained is compared with the sign of a value obtained by differentiating the waveform of one line of the target image similarly obtained from the acquired waveform of the infrared light emitted from the infrared LED 27.
[0082]
One example is shown as a waveform in FIG. When there is no image, the intensity of the transmitted infrared light transmitted through the sheet is high, and the waveform of the transmitted image information is located in a positive region. When there is an image, the intensity of the transmitted infrared light transmitted through the sheet is weak, and the waveform of the transmitted image information is located in a negative region.
[0083]
The broken line shows the waveform of the transmitted image information by infrared light when the sheet is not multi-fed. The waveform indicated by the broken line is substantially the same as the waveform in one line of the target image acquired from the acquired waveform of the reflected image information acquired from the visible light. However, when the sheets are multi-fed, the waveform based on the transmission image information is a solid line waveform. The CPU circuit 5 determines whether the value obtained by differentiating the image information waveform obtained from the reflected image information and the transmitted image information in one line of the same target image is positive or negative. If there is a difference, it is determined to be a double feed.
[0084]
As described above, when image information is acquired by irradiating a sheet with infrared rays, when an operation of irradiating infrared rays only on a part of the sheet or only one line in the conveyance direction to detect double feeding of the sheet is performed, The amount of information on which the circuit 5 performs image processing can be reduced to speed up the operation of detecting a multi-feed sheet and reduce the production cost of the multi-feed sheet detection device.
[0085]
If the amount of transmitted infrared light is equal to or less than the set value even though the sheet is irradiated with infrared light by the infrared LED, the CPU circuit 5 determines that it is not possible to detect whether or not the conveyed sheet is a double feed. Then, the warning means 16 is activated. By operating the warning unit 16 to notify the user that the operation of detecting the multi-feed of the sheet cannot be performed, it is possible to prevent the multi-feed in the case where the image acquisition is continued without detecting the multi-feed of the sheet. It is possible to prevent image information from being lost in the sending portion.
[0086]
The CPU circuit 5 also activates the warning means 16 in order to make the user recognize that the double feed has occurred even when the double feed of the sheet is detected. By operating the warning unit 16, it is possible to prevent image information omission in the double feed portion that occurs when the image acquisition is continued while the double feed of the sheet occurs.
[0087]
In order to detect whether or not a sheet is multi-fed, using the acquired waveform of image information obtained by visible light and the acquired waveform of transmitted image information by infrared light, the acquired waveform of reflected image information by visible light is used as the target image. Whether the sheet is multi-fed by utilizing that the acquired waveform of transmitted image information by infrared indicates the position information and infrared transmission intensity of the same target image. May be detected. The configuration of the multi-feed sheet detection device in this case is the same as the configuration shown in FIGS.
[0088]
The CPU circuit 5 occupies an image in one line of the target image (a line along the sub-scanning direction (sheet conveying direction)) acquired by the waveform of the reflected image information obtained from the light receiving element 12an (or the light receiving element 25an). By comparing the ratio (image ratio) with the ratio (image ratio) of the image in one line of the target image similarly acquired from the light receiving sensor 26 using the acquired waveform, the image ratio in visible light and the image ratio in infrared light are compared. If a difference of more than a predetermined ratio occurs, it is determined that a double feed has occurred.
[0089]
As described above, when the transmission of the image is performed by irradiating the sheet with the infrared light, when the operation of detecting the double feed of the sheet by irradiating the infrared light only on a part of the sheet or only one line in the conveyance direction is performed, The amount of information for which the CPU circuit 5 performs image processing can be reduced to speed up the operation of detecting a multi-feed sheet and reduce the production cost of the multi-sheet detection device.
[0090]
In the above description, when the infrared light emitted to the sheet by the infrared LED 15 does not pass through the sheet at all, the CPU circuit 5 determines that the multi-feed of the conveyed sheet cannot be detected, and issues a warning unit 16. Activate By operating the warning means 16 to notify the user that the operation of detecting the multi-feed of the sheet cannot be performed, it is possible to prevent the multi-feed of the sheet from being detected if the multi-feed of the sheet cannot be detected. It is possible to prevent image information from being lost in the sending portion.
[0091]
The CPU circuit 5 also activates the warning means 16 in order to make the user recognize that the double feed has occurred even when the double feed of the sheet is detected. By operating the warning unit 16, it is possible to prevent image information omission in the double feed portion that occurs when the image acquisition is continued while the double feed of the sheet occurs.
[0092]
In the above configuration, if the image reading device 22 can read only one side of the sheet, the RGB three-color LED is unnecessary as in the line sensor unit 3A of the image reading device 30 shown in FIG. Is used. Further, in this case, as in the image reading apparatus 31 shown in FIG. 11, the infrared LED 15 may be housed in the case 19, the light receiving sensor 26 may be housed in the case 20, and the case 18 may be omitted. The image reading device 31 shown in FIG. 11 has a configuration in which an infrared LED 27 and a light receiving sensor 26 are added to a conventional image reading device.
[0093]
The image reading devices 22, 28, 29, 30, and 31 can transfer a sheet having the same thickness as two or more stacked sheets or a sheet having various thicknesses. Are provided with the multi-feed sheet detecting devices 21 and 28 that prevent erroneous recognition of multi-feed, so that the image of the sheet can be reliably read without dropping image information.
[0094]
【The invention's effect】
The multi-feed sheet detection device of the present invention does not detect whether or not a sheet is multi-fed according to the received light intensity when the transmitted infrared light transmitted through the sheet is received by the infrared receiver, but detects the transmitted infrared light from the transmitted infrared light. Since multifeeding is detected by using the obtained image information, even if a sheet having the same thickness as two or more sheets is conveyed, or a sheet having various thicknesses is detected. Even if the sheet is conveyed, it is possible to prevent the sheet from being erroneously recognized as a double feed.
[0095]
The image reading apparatus according to the present invention is configured such that even if a sheet having the same thickness as two or more stacked sheets is conveyed, or if sheets of various thicknesses are conveyed, the sheet is multi-fed. Since the multi-feed sheet detection device that prevents misrecognition is provided, it is possible to reliably read the sheet image without dropping image information.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a multi-feed sheet detection device according to a first embodiment of the present invention and an image reading device including the multi-feed sheet detection device.
FIG. 2 is a diagram for explaining an image reading operation and a multi-feed detection operation of a sheet having an image formed on only one side in the image reading apparatus of FIG. 1;
FIG. 3 is a diagram for explaining an image reading operation and a multi-feed detection operation of a sheet on which an image is formed only on one side in the image reading apparatus of FIG. 1; FIG. 9 is a diagram for explaining a detection operation when the detection is performed.
FIG. 4 is a diagram illustrating a double-feed detection operation when a sheet having an image formed on both sides is sent in a state where an image on a sheet having an image formed on one side is read in the image reading apparatus of FIG. 1; FIG.
FIG. 5 is a view for explaining an image reading operation and a double-feed detecting operation of a sheet having images formed on both sides in the image reading apparatus of FIG. 1;
FIG. 6 is a diagram for explaining an image reading operation and a double-feed detecting operation when sheets having images formed on both sides are sent in an overlapping manner in the image reading apparatus of FIG. 1;
FIG. 7 is a schematic diagram of a multi-feed sheet detection device according to a second embodiment and an image reading device including the multi-feed sheet detection device.
FIG. 8 illustrates an infrared LED and a light receiving sensor fixed at the center of a sheet conveyance path, and detects multi-feeding of sheets based on image information by a line along one sheet conveyance direction. FIG.
FIG. 9 is a graph for comparing and contrasting the intensity of infrared light expected from reflected image information with the intensity of infrared light upon double feeding.
FIG. 10 is a schematic diagram of an image reading apparatus according to still another embodiment.
FIG. 11 is a schematic view of an image reading apparatus according to still another embodiment.
FIG. 12 is a control block diagram of a conventional image reading apparatus.
FIG. 13 is a graph showing infrared light reception intensity in a conventional image reading apparatus.
[Explanation of symbols]
P, P1, P2, P3 sheet
G1 Reflected image information
G2 Transmission image information
G3 Transmission image information
G4 transmission image information
G5 Transmission image information
G7 Transmission image information
G11 Reflected image information
G12 Reflected image information
G13 Reflected image information
G14 Reflected image information (first superimposed image information)
G15 Transmission image information (second overlay image information)
G16 Transmission image information
G17 Reflected image information
G18 Reflected image information
G19 Reflected image information
G20 Transmission image information
G21 Transmission image information
2 Line sensor unit
3 Line sensor unit
5 CPU circuit (judgment means)
11 RGB three-color LED (first irradiation means)
12. Light receiving sensor (first light receiving means)
12a light receiving element
Light receiving element corresponding to 12an infrared LED
13 RGB three-color LED (third irradiation means)
14. Light receiving sensor (second light receiving means, third light receiving means)
15 infrared LED (second irradiation means)
16 Warning means
17 cases
18 cases
19 cases
20 cases
21 Double feed sheet detection device
22 Image reading device
25 light receiving sensor (third light receiving means)
25a light receiving element
Light receiving element corresponding to 25an infrared LED
26 light receiving sensor (second light receiving means)
27 infrared LED (second irradiation means)
28 Double feed sheet detection device
29 Image reading device
30 Image reading device
31 Image reading device

Claims (18)

First irradiating means for irradiating the sheet on which the image is formed,
A first light receiving unit that receives reflected light from the sheet irradiated by the first irradiation unit;
Second irradiating means for irradiating the sheet with irradiation light having different characteristics from irradiation light of the first irradiation means;
A second light receiving unit that receives light transmitted by the second irradiation unit and transmitted through the sheet;
Determining means for comparing the reflected image information obtained by the first light receiving means and the transmitted image information obtained by the second light receiving means to determine whether or not the sheet is multi-fed;
A multi-feed sheet detecting device comprising: First irradiating means for irradiating the sheet on which the image is formed,
A first light receiving unit that receives reflected light from the sheet irradiated by the first irradiation unit;
Second irradiating means for irradiating the sheet with irradiation light having different characteristics from irradiation light of the first irradiation means;
A second light receiving unit that receives light transmitted by the second irradiation unit and transmitted through the sheet;
Either one of the reflected image information obtained by the first light receiving means and the transmitted image information obtained by the second light receiving means is inverted and compared with the other image information. Determining means for determining whether or not the sheets are multi-fed based on whether or not they are the same,
A multi-feed sheet detecting device comprising: First irradiating means for irradiating the sheet on which the image is formed,
A first light receiving unit that receives reflected light from the sheet irradiated by the first irradiation unit;
Second irradiating means for irradiating the sheet with irradiation light having different characteristics from irradiation light of the first irradiation means;
A second light receiving unit that receives light transmitted by the second irradiation unit and transmitted through the sheet;
Third irradiating means for irradiating the back surface of the sheet irradiated by the first irradiating means;
Third light receiving means for receiving reflected light from the back surface irradiated by the third irradiation means,
First superimposed image information obtained by superimposing the reflected image information obtained by the first light receiving means and the inverted reflected image information obtained by the third light receiving means, and obtained by the second light receiving means The second superimposed image information obtained by superimposing the transmitted image information and the reflected image information obtained by the third light receiving means is inverted, and compared with the other superimposed image information. Judging means for judging whether or not the sheet is multi-fed based on whether or not the first overlay image information and the second overlay image information are the same;
A multi-feed sheet detecting device comprising: First irradiating means for irradiating the sheet on which the image is formed,
A first light receiving unit that receives reflected light from the sheet irradiated by the first irradiation unit;
Second irradiating means for irradiating the sheet with irradiation light having different characteristics from irradiation light of the first irradiation means;
A second light receiving unit that receives light transmitted by the second irradiation unit and transmitted through the sheet;
Third irradiating means for irradiating the back surface of the sheet irradiated by the first irradiating means;
Third light receiving means for receiving reflected light from the back surface irradiated by the third irradiation means,
First superimposed image information obtained by superimposing inverted reflected image information obtained by the first light receiving means and reflected image information obtained by the third light receiving means, and obtained by the second light receiving means The transmitted image information is compared with the second superimposed image information obtained by superimposing the reflected image information obtained by the third light receiving means, and the first superimposed image information and the second superimposed image information are the same. Determining means for determining whether or not the sheet is multi-fed based on whether or not,
A multi-feed sheet detecting device comprising: The second irradiating unit is capable of irradiating a part of the conveyed sheet, and the determining unit is configured to determine an image ratio of the reflection image information corresponding to a part of the sheet obtained by the first light receiving unit and the image ratio. 2. The method according to claim 1, wherein the sheet is determined to be multi-fed when a difference between the image ratio of the transmission image information of a part of the sheet obtained by the second light receiving unit and the image ratio exceeds a predetermined value. The double feed sheet detecting device according to the above. The second irradiating unit is capable of irradiating a part of the conveyed sheet, and the determining unit calculates a value obtained by differentiating the reflected image information corresponding to the part of the sheet obtained by the first light receiving unit. The sheet is determined to be multi-fed when a difference of a predetermined value or more occurs from a value obtained by differentiating the transmission image information of a part of the sheet obtained by the second light receiving unit. Item 2. The multi-feed sheet detection device according to Item 1. The determining means compares the reflected image information obtained by the first light receiving means with the transmitted image information obtained by the second light receiving means, and determines the reflected image information of the sheet on which an image is formed only on one side. 7. The apparatus according to claim 1, wherein it is determined whether or not the sheet is multi-fed based on whether or not the transmission image information and the transmission image information are the same. 8. Double feed sheet detection device. The determination unit compares the reflected image information obtained by the first light receiving unit with the transmitted image information obtained by the second light receiving unit, and compares the reflected image information on one side of a sheet on which images are formed on both sides. 7. The apparatus according to claim 1, wherein it is determined whether or not the sheet is multi-fed based on whether or not information and the transmitted image information are the same. The double feed sheet detecting device according to the above. The multi-feed sheet detecting apparatus according to claim 3, wherein the second light receiving unit and the third light receiving unit are a common light receiving unit. 9. The multi-feed sheet detecting device according to claim 1, wherein the first irradiation unit and the second irradiation unit irradiate a part of the sheet. 10. 5. The multi-feed sheet detecting device according to claim 3, wherein the first irradiating unit, the second irradiating unit, and the third irradiating unit irradiate a part of the sheet. 6. The multi-feed sheet detecting apparatus according to any one of claims 1 to 11, wherein the first irradiating unit and the second irradiating unit are housed in a common case. The multi-feed sheet detecting apparatus according to claim 1, wherein the first irradiating unit and the second irradiating unit are housed in separate cases. 14. The multi-feed sheet detecting device according to claim 1, wherein the second irradiation unit emits infrared light. The multi-feed sheet detecting device according to any one of claims 1 to 14, wherein the second irradiation unit includes an infrared LED that emits infrared light. 16. The multi-feed sheet detecting apparatus according to claim 1, wherein the second irradiation unit does not emit light when the determination unit does not operate. 17. The apparatus according to claim 1, further comprising: a warning unit that warns that the determination unit is inoperable when the amount of light received by the second light receiving unit is equal to or less than a set value. The double feed sheet detecting device according to the above. Image reading means for reading an image formed on the sheet,
A multi-feed sheet detection device that detects whether or not the conveyed sheets are overlapped,
The multi-feed sheet detection device according to any one of claims 1 to 17, wherein the image reading unit includes the first irradiation unit and the first light receiving unit of the multi-feed sheet detection device. Means, and an image reading apparatus for reading an image by the third irradiation means and the third light receiving means.

Images